Pituitary and Thyroid Glands

Question 1

Where does the pituitary gland lie?

Answer 1

Lies in a packet (sella turcica) of the sphenoid bone at teh base of the brain just below the hypothalamus

Question 2

How is the pituitary connected to the hypothalamus?

Answer 2

By the infundibulum (pituitary stalk)

Question 3

What are the different parts to the pituitary?

Answer 3

2 adjacent lobes

1. Anterior pituitary (adenohypophysis)
   - develops from a dorsal outgrowth from the wall of the embryonic pharynx
2. Posterior pituitary (neurohypophysis)
   - develops from a down growth from the diencephalon

Question 4

Where does the adenohypophysis develop from?

Answer 4

Dorsal outgrowth from the wall of the embryonic pharynx

Question 5

Where does the neurohypophysis develop from?

Answer 5

Down growth from the diencephalon

Question 6

Where do the neurons in the neurohypophysis come from?

Answer 6

Axons of the supraoptic and paraventricular nuclei in the hypothalamic ventricle down the infundibulum into the neurohypophysis

• Neurons do not synapse with others - their terminals end directly on capillaries, releasing hormones into the blood

Question 7

Are there any neural connections between the hypothalamus and the adenohypophysis?

Answer 7

No important connections

Question 8

What capillaries combine to form the hypothalamo-hypophyseal portal vessels?

Answer 8

Capillaries from the median eminence

Question 9

List the hypothalamus-pituitary hormones (adenohypophysis) axises

Answer 9

1. GHRH –> GH (somatotrophs -50%) –> multiple
2. GnRH –> FSH/LH (gonadotrophs - 10%) –> ovaries/testes
3. CRH –> ACTH (corticotrophs - 10-15%) –> adrenal cortex
4. TRH –> TSH (thyrotrphs - 5%) –> thyroid
5. Dopamine –> Prolactin (-ve; lactotrophes - 20%) –> breasts/uterus

Question 10

What hormones are produced from the neurohypophysis?

Answer 10

Oxytocin

ADH/vasopressin

Question 11

What hormone is important in labour and pregnancy and how does it work?

Answer 11

Oxytocin

• Stimulates cervical dilatation and uterine contractions
• Suckling reflex in mammary glands

Question 12

What hormone causes sexual arousal that’s secreted from the neurohypophysis?

Answer 12

Oxytocin

Question 13

Define diabetes insipidus

Answer 13

Lack of ADH from neurohypophysis

Question 14

List common disorders of the anterior pituitary

Answer 14

– Diabetes insipidus (lack of ADH)

– Syndrome of inappropriate anti-diuretic hormone (SIADH)

Question 15

What is the clinical features of diabetes insipidus?

Answer 15

• Lack of ADH
• No water reabsorption
• Passage of large volumes of DILUTE URINE (>3L/day)
• Polyuria, polydipsia, noctouria
• LOW URINE OSMOLALITY and high plasma osmolality

Question 16

Describe ADH action

Answer 16

• AVPR2 translocation on basolateral membrane of collecting duct of kidneys (exocytosis)
• Increase aquaporin channels (AQ2) and water reabsorption

Question 17

What are the causes of diabetes insipidus?

Answer 17

1. Cranial cause
   - deficiency of ADH (idiopathy/genetic)
   - trauma/tumour/infection/inflammation
2. Nephrogenic cause
   - resistance to ADH
   - genetic: AVPR2 mutation
   - iatrogenic: e.g. lithium drugs
   - secondary: metabolic dysfunction or renal disease

Question 18

How would you test for the cause of diabetes insipidus?

Answer 18

Water Deprivation Test

1. Deprive patients of fluid for 8 hours
2. Measure plasma and urine osmolality every 2-4hours
3. Give synthetic ADH (ddAVP) and re-asses urine osmolality

Results:

Normal Patient

• starting plasma osmolality: normal 300mOsm/L
• 8hour urine osmolality: >600mOsm/L (water retained
• after ddAVP >600mOsm\L

Cranial DI

• starting plasma osmolality: HIGH (low [water])
• 8hour urine osmolality: LOW <300mOsm\L (NO ADH SO NO RETENSION)
• after ddAVP: HIGH >600mOsm/L (Synthetic ADH acts on kidneys to retain water)

Nephrogenic DI

• starting plasma osmolality: HIGH (low [water])
• 8hour urine osmolality: LOW
• after ddAVP: LOW

Question 19

Tx Diabetes Insipidus

Answer 19

1. Cranial cause
   - Desmopressin (ADH analogue)
   - Orally/nasal
   - Spray/injection
   * monitor [Na]plasma and osmolality
2. Nephrogenic cause
   - high doses ddAVP
   - treat underlying cause (e.g. excise tumour)

Question 20

Where is the pituitary located relative to the optic chiasm?

Answer 20

Pituitary located inferiorly to optic chiasm

Question 21

What is the name give to pituitary tumours

Answer 21

Adenoma

Question 22

What is the potential consequence of a pituitary tumour?

Answer 22

Adenoma can push on the optic chiasm (which lies superior to the pituitary)
Can cause bitemporal hemianopia (loss of peripheral vision)

Question 23

List the hormones involves in secretory pituitary adenomas

Answer 23

1. Prolactinoma - releases excess prolactin
   - commonest (30%)
2. Cushing’s disease - ACTH excess
   - 20%
3. Acromegaly - GH excess
   - 15%
4. TSHomas - TSH excess
   - <1% very rare

Question 24

What condition is caused secretory pituitary adenoma GH secretion?

Answer 24

Acromegaly

Question 25

What condition is caused secretory pituitary adenoma prolactin secretion?

Answer 25

Prolactinoma

Question 26

What condition is caused secretory pituitary adenoma TSH secretion?

Answer 26

TSHoma

Question 27

What condition is caused secretory pituitary adenoma ACTH secretion?

Answer 27

Cushing’s Disease

Question 28

What are the clinical features and management of prolactinomas?

Answer 28

Clinical features:

• galactorrea: milky nipple discharge
• menstrual disturbance and subfertility in women
• reduced libido and erectile dysfunction in men

Management

• Dopamine agonist (Cabergoline)
• Surgery if large tumour + bitemporal hemianopia

Question 29

What is Cabergoline? And what is it used to treat?

Answer 29

Dopamine agonist

Used to treat prolactinomas

Increase in dopamine negatively inhibits prolactin secretion from the adenohypophysis

Question 30

What is acromegaly?

Answer 30

Excessive production of GH (and IGF-1) in adults

Question 31

What does excessive production of GH cause in children?

Answer 31

Gigantism

Question 32

What are the clinical features of acromegaly?

Answer 32

• Symptoms
– Sweats, headache, tiredness, increase in ring or
shoe size, joint pains

• Signs
– Coarse facial appearance
– Enlarged tongue
– Enlarged hands and feet
– Visual field loss

• Complications
– Hypertension, diabetes or impaired glucose
tolerance, increased risk of bowel cancer, heart
failure

Question 33

Dx acromegaly

Answer 33

1. Glucose tolerance test
   - Glucose fails to suppress GH
   - May reveal underlying DM or IGT
2. IGF-1 level
   - Produced in the liver in response to GH
   - Long half-life; protein-bound
3. Pituitary MRI
   - macroadenoma >1cm

Question 34

Management of acromegaly

Answer 34

1. Surgically
   - Trans-sphenoidal or trans-cranial route
2. Medical
   - Before and after surgery
   - Somatostatin analogues to inhibit GH secretion
3. Radiotherapy
   - Treat residual tumour
   - Risk of hypopituitarism and long-term problems

Question 35

What can inhibit GH secretion?

Answer 35

Somatostatins

Question 36

Define hypopituitarism

Answer 36

Failure of adenohypophysis function

Question 37

What is the name given when hypopituitarism affects ALL hormones?

Answer 37

Panhypopituitarism

Question 38

What drug would you give first in panhypopituitarism?

Answer 38

Cortisol

Question 39

What is Sheehan’s syndrome?

Answer 39

Ischaemic necrosis due to blood loss/hypovolaemic shock during or after childbirth

IN MOTHER

Question 40

What is apoplexy?

Answer 40

Unconsciousness or incapacity resulting from a cerebral haemorrhage or stroke.

Question 41

Define necrosis

Answer 41

The death of some or all of the cells in an organ or tissue, caused by disease, physical, or chemical injury, or interference with blood supply (ischaemia)

Question 42

How many layers of cells is the thyroid follicles made up of?

Answer 42

A single layer of cuboidal epithelial cells

And basement membrane

Question 43

Describe the structure of a thyroid follicle

Answer 43

A single layer of cuboidal epithelial cells
And basement membrane
Surrounding a lumen containing colloid (containing largely thyroglobulin)

Question 44

What is the epithelial difference in follicular epithelial cells during suppression and stimulation?

Answer 44

• When stimulated = CUBOIDAL; and lumen is depleted of colloid
• When suppressed = SQUAMOUS; and colloid accumulates in lumen

Question 45

Which is the more important thyroid hormone?

Answer 45

T3

Tri-iodothyronin

Question 46

How is T4 converted into T3?

Answer 46

T4 converted into T3 by enzymes called 5’deiodinases in target cells

THEY REMOVE 1 IODINE GROUP OFF T4 TO MAKE T3

Question 47

Where is iodine naturally found?

Answer 47

Sea water
Fruit
Vegetables

Question 48

What is the required daily amount of iodine?

Answer 48

150-300ug/day

Question 49

What is the characteristic of iodine deficiency?

Answer 49

Goitre

Question 50

Describe thyroid hormone biosynthesis

Answer 50

1. Iodide actively co-transported with Na+ across basolateral membrane of epithelial cells (iodide trapping) against a chemical gradient. Na+ is pumped back out by Na+/K+-ATPase
2. Negatively charge iodide diffuses to the apical membrane and is transported by PENDRIN (integral membrane protein) into colloid
3. Iodide is oxidised to iodine in the colloid by THYROID PEROXIDASE
4. Iodine is attached to rings of tyrosine in thyroglobulin - by THYROID PEROXIDASE
   (thyroglobulin is synthesised by eER in the thyroid follicular cell and exocytosed into the colloid)
5. Iodine may be added to either of two positions of a given tyrosine within a thyroglobulin
   - a tyrosine with 1 iodine attached = mono-iodo-tyrosine (MIT)
   - a tyrosine with 2 iodine attached = di-iodo-tyrosine (DIT)

• DIT + DIT = T4
• MIT + DIT = T3

6. Once formed, extensions of colloid- facing membranes of follicular epithelial cells engulf portions of the colloid with its iodinated thyroglobulin by endocytosis
7. Within the cell, thyroglobulin-MIT/DIT is brought into contact with lysosomes, which proteolyse off thyroglobulin releasing T3/T4 (hydrolysis)
8. Free T3/T4 then diffuse out of the follicular epithelial cells (via monocarboxylase transporter - MCT) into the interstitial fluid and then into circulation

Question 51

What thyroid hormone is released in greater quantity?

Answer 51

T4

Thyroxine

Question 52

How does thyroid hormone circulate?

Answer 52

0. 5% Free

99. 5% bound to thyroid binding protein (transthyretin or albumin)

Question 53

What type of receptors for thyroid hormones act on?

Answer 53

Nuclear receptors

alpha and beta

Question 54

What level of action does thyroid hormones work on?

Answer 54

Inducing gene transcription and protein systhesis

Question 55

How is thyroid hormone regulated?

Answer 55

1. Neural inputs from higher cortex
2. Hypothalamus secretes TRH to anterior pituitary
3. Adenhypophysis secretes TSH to thyroid gland
4. Thyroid gland synthesises and releases T3/T4 into the blood
5. T3/T4 binds to thyroid binding proteins (transthyretin/albulmin)
6. T3/T4 negative control feedback inhibits adenohypophysis (TSH) and hypothalamus (TRH) axis

Question 56

What is the biochemical findings in primary hypothyroidism?

Answer 56

• Elevated TSH (from anterior pituitary)

- Decreased T4 (dysfunctional thyroid)

Question 57

What is the biochemical findings in secondary hypothyroidism?

Answer 57

• Decreased TSH

- Decreased T4

Question 58

What is the biochemical findings in primary hyperthyroidism?

Answer 58

• Decreased TSH

- Elevated T4

Question 59

Define euthyroid

Answer 59

Euthyroid is the state of having normal thyroid gland function

Question 60

What is sick euthyroid?

Answer 60

• Euthyroid sick syndrome is low serum levels of thyroid hormones in clinically euthyroid patients with non-thyroidal systemic illness
• Diagnosis is based on excluding hypothyroidism
• Treatment is of the underlying illness; thyroid hormone replacement is not indicated.

Question 61

What is the aetiology of hyperthyroidism?

Answer 61

• Autoimmune - Most common (Graves’ Disease)
• Toxic adenoma
• Multinodular goitre
• Thyroiditis
• Excess administration of thyroxine

Question 62

What are the clinical manifestations of hyperthyroidism?

Answer 62

*General increase in metabolism activity

• Weight loss
• Tremer
• Heat intolerance
• Diarrhoea
• Tachycarida and increased cardiac output
• Hypertension
• Palpitations
• Sweating
• Hyperkinetic (too much energy)

Question 63

What are the specific characteristics to Graves’ Disease

Answer 63

Graves’ disease is an autoimmune (most common) form of hyperthyroidism

1. Dysthyroid eye disease (Ophthalmopathy)
   - 50% patients
   - Periorbital oedema
   - Proptosis (bulging of eye)
   - Diplopia (double vision)
2. Dermopathy (skin condition characterised by red swollen skin)
   - Pretibial myxoedema
   - Thyroid acropachy (digital clubbing, swelling of digits and toes)

Question 64

Tx Grave’s disease

Answer 64

Graves’ disease is a form of hyperthyroidism

1. Thyronamines (e.g. Carbomazole)
2. Radio-iodine therapy
   - destroys thyroid tissue by b-emission
   - may worsen eye disease
   - defer conception for at least 4 months
   - MAJOR SIDE EFFECT: hypothyroidism
3. Surgical removal
   - Complications: haemorrhage, recurrent laryngeal nerve palsy (voice change), permanent hypocalcaemia, hypothyroidism
4. iodine drugs
   - reduces vascularity
   - increases colloid storage

Question 65

What sex and age group is Graves’ disease most commonly in

Answer 65

Female

20-40

Question 66

What is Graves’ disease characterised by?

Answer 66

• Hyperthyroidism
• Diffuse goitre

Thyroid gland is diffusely hyperplastic and hperaemic
- bruit on auscultation

Can also present with

• dysthyroid eye disease (omphthalomopathy)
• dermopathy

Question 67

What are the main causes of hypothyroidism?

Answer 67

1. Autoimmune thyroid disease (Hashimotos)
   - destruction of the thyroid gland
   - anti-thyroperoxidase antibodies)
2. Thyroiditis
3. Thyroidectomy
4. Following radio-iodine therapy
5. Drug-induced
   - e.g.: lithium
6. Pituitary disease
   - secondary hypothyroidism
7. Severe iodine deficiency

Question 68

What are the symptoms of hypothyroidism?

Answer 68

*General reduction in metabolic activity

• weight gain
• depression
• lethargy
• constipation
• cold intolerance (in severe cases: hypothermia)
• hoarseness (due to accumulation of mucopolysaccharides)
• menorrhagia (abnormal/heavy bleeding cycle)
• bradycardia
• dry skin
• coarse, thin hair
• anaemia
• slow relaxing reflexes
• may present with goitre
• mental impairment (psychosis)

Question 69

Tx for hypothyroidism

Answer 69

Levothyroxine

- a manufactured form of the thyroid hormone, thyroxine.

Question 70

What condition results from anti-thyropereoxidase antibodies?

Answer 70

Hashimoto’s Disease

Question 71

What condition results from anti-TSH receptor antibody (thyroid stimulating)?

Answer 71

Grave’s disease

Question 72

What condition results from anti-TSH receptor antibody (thyroid growth)?

Answer 72

Goitre

Question 73

What condition results from anti-TSH receptor antibody (thyroid receptor blocking)?

Answer 73

Hypothyroidism

Primary myxoedema

Question 74

What is the name of the condition of hypothyroidism in children? And what does it cause?

Answer 74

Cretinism

Stunned physical and mental growth

Question 75

What is the name of the condition of hypothyroidism in adults? And what does it cause?

Answer 75

Myxoedema

• Elderly females
• Atrophic thyroid = fibrosis
• Severe hypothyroidism = hypothermia and coma
• Symptoms depend on hormone deficiency

(if due to anti-thyroidperoxidase Ab = Hashimoto’s)

Question 76

What are they metabolic actions of T3?

Answer 76

• Increases whole-body basal metabolic rate
• Nuclear alpha and beta receptors
• Increases ATP utilisation by increasing Na+/K+-ATPase and increasing mitochondria oxidative metabolism
• Increase lipolysis is also stimulated by cAMP-dependent activation of hormone sensitive lipase
• Increase glycogenolysis and gluconeogenesis (thermogenesis fuel)

Question 77

How does T3 increase energy production?

Answer 77

• Increases ATP utilisation by increasing Na+/K+-ATPase and increasing mitochondria oxidative metabolism